Guidance of cellular nematic elastomers into shape-programmable living surfaces
Summary
Engineering living materials that autonomously morph into predetermined shapes holds potential for synthetic morphogenesis and soft robotics. Harnessing cellular tissues to self-organize and generate forces offers a promising route toward this goal. However, controlling tissue mechanics to direct morphogenesis remains challenging. We introduce a strategy to program tissue-shape transformations through nematic organization of cellular forces. By controlling nematic order and topological def
Content
# Guidance of cellular nematic elastomers into shape-programmable living surfaces
*Published: 2026 Apr 16*
Engineering living materials that autonomously morph into predetermined shapes
holds potential for synthetic morphogenesis and soft robotics. Harnessing
cellular tissues to self-organize and generate forces offers a promising route
toward this goal. However, controlling tissue mechanics to direct morphogenesis
remains challenging. We introduce a strategy to program tissue-shape
transformations through nematic organization of cellular forces. By controlling
nematic order and topological defects, we generate tissues programmed with
specific stress fields. Using a theoretical framework coupling contractile
nematics with thin-sheet mechanics, we show that nematically guided active
stresses can drive morphogenesis through Gaussian morphing. Experimentally,
detachment of nematic tissues triggers out-of-plane deformations, generating
reproducible three-dimensional shapes. Integrating contractility and nematic
patterning, our approach establishes a framework for designing
shape-programmable living surfaces.
DOI: 10.1126/science.adz9174